Power Tool and Battery Support Racks and Methods of Manufacturing

ABSTRACT

A support rack and method of manufacture thereof are provided for retaining a power hand tool or a battery pack on a wall surface. The support rack when configured for storing a power hand tool includes a mounting panel for connection to the wall surface, a support panel that extends from the mounting panel, and at least one projecting structure that extends upwardly from the support panel. The projecting structure is customized in shape and size to releasably engage in a close frictional fit with at least one corresponding interface element (aperture or slot) provided on the power hand tool. The support rack is integrally formed as a unitary piece from a plastic material and thus includes no metallic or conductive components configured to provide power or electrical charging to the power hand tool (or battery pack), thereby providing a reliable physical support for same.

CROSS-REFERENCE

This application is a continuation in part of, and claims the priorityof, each of the following co-pending applications: U.S. patentapplication Ser. No. 17/550,645, filed Dec. 14, 2021; U.S. Design PatentApplication 29/806,099, filed Sep. 1, 2021; and U.S. Design PatentApplication 29/802,321, filed Aug. 4, 2021 (now U.S. Design Pat. No.D990,422, to be issued Jun. 27, 2023). The disclosures of which areincorporated by reference herein.

TECHNICAL FIELD

The invention relates generally to organization and storage devices, andmore specifically relates to support structures for mounting handheldpower tools and their associated battery packs on a generally verticalwall surface.

BACKGROUND

Handheld power tools that are battery-powered are present in almostevery household and in many businesses. These power tools can includeanything from cordless drills and sanders to lawn care devices (e.g.,leaf blowers and the like). Such power tools provide the convenience ofworking wirelessly throughout a house or building and/or thesurroundings outside same. It is typical for certain brands andmanufacturers of such power tools to use a unique battery pack or basethat can work with many different types of power tools, as toolmanufacturers realized that operators will want battery power formultiple types of tools, but only one tool is typically used at a timeby the operator. As a result, battery packs can be readily moved betweencharging stations and any of the power tools that may need powered atthat time by the battery pack(s).

Also as a result, it is typical for owners of these sets of power toolsto have extra battery packs on hand for switching into service when abattery pack on a power tool is exhausted of its electrical energy.Especially with spare or additional battery packs, these elements mustbe stored separately from the power tools because the power tools areoften engaged with other battery packs or chargers. Furthermore, it isoften the case that the additional battery packs cannot just be storedon chargers because such chargers are space-consuming and only chargeone or two battery packs at a time. It is desirable to have goodorganization for storing such elements because tool storage spaces tendto be easily prone to disorganization and messiness, which can make itmore time-consuming and difficult to find and replace a battery packwhen needed during work with the power tools. Moreover, battery packsand tools are more prone to accidental damages and/or loss when notstored in an organized manner.

Present solutions for assisting with storage of tools are notwell-configured for these types of handheld power tools and theirbattery packs. British Patent No. GB 2 347 884 describes a device forsuspending or attaching a hand tool, but such a device has multipleconnecting parts and locking components that are complex to manufactureand only secure a single device, in any event. Another prior design isdescribed in International PCT Patent Application Publication No.WO2020/037371, but this holder device is only configured to receive oneor more batteries. To this end, the holder in '371 is not configured toprovide storage solutions relevant to storing the power hand toolsthemselves, and the holder seemingly must also be mounted horizontallyand/or include locking structures which limit the use conditions for theholder while also increasing manufacturing complexity. Furthermore, manyother commercially-available designs also include integrated chargingcapabilities which would then require further connection to an externalpower supply to be fully functional. Each of these prior designstherefore places significant limits on how they can be used, whichreduces the likelihood of encouraging and achieving the desiredorganization of tools and battery packs and protection from accidentaldamages of these.

It would therefore be desirable to provide a support rack that bettersupports and organizes power hand tools or battery packs, whileproviding a simplified construction and better use configurations,including for wall-mounted organization of same.

SUMMARY

These and other technical problems are addressed by the tool supportrack in accordance with embodiments of this invention. The tool supportrack is configured to retain a power hand tool on a wall surface. In afirst set of embodiments, the support rack includes a mounting panel, asupport panel, and at least one projecting structure. The mounting panelis configured to be positioned in engagement with the wall surface, andthe mounting panel includes at least one fastener aperture sized toreceive a fastening element that removably couples the mounting panel tothe wall surface. The support panel is connected to and extendstransversely from the mounting panel, with the support panel includingan upper surface and a lower surface. The projecting structure extendstransversely and upwardly from the upper surface of the support panel.The projecting structure is customized in shape and size to releasablyengage in a frictional fit with at least one corresponding interfaceaperture or slot provided on the power hand tool. Advantageously, thesupport rack includes no metallic or conductive components configured toprovide power or electric charging to the power hand tool. As such, thesupport rack provides only a physical support for the power hand tool onthe wall surface. The support rack is easy and inexpensive tomanufacture and customized for a certain type (or brand) of power handtool so that owners of such power hand tools can better store andorganize tools without filling up shelf space or other surfaces that arebetter used for other types of tools and devices.

In one embodiment, each of the mounting panel and the support panel is aplanar panel. The support panel extends perpendicular to the mountingpanel in such an embodiment, and such that the support panel is orientedhorizontally when the support panel is secured to the wall surface,which is generally vertical in orientation.

In another embodiment, the mounting panel defines a U-shapedconstruction with mounting tabs extending vertically above a remainderof the mounting panel on opposite lateral ends of the mounting panel.Each of the mounting tabs includes one of the fastener apertures, whichresults in a plurality of fasteners being used to secure the toolsupport rack to the wall surface.

In a further embodiment, the tool support rack is formed from andconsists of a plastic material only. For example, all of the mountingpanel, the support panel, and the projecting structure are formedintegrally as a unitary piece from the plastic material. The plasticmaterial may be formed by additive manufacturing methods such as 3Dprinting, or alternatively, injection molding processes.

In yet another embodiment, the mounting panel and the support paneldefine a thickness and size configured to support a full weight of thepower hand tool when the power hand tool is engaged in the frictionalfit with the projecting structure. In other embodiments, a plurality ofthe tool support racks may be combined in use to support larger toolshaving multiple interface elements, although it is preferred to supportthe power hand tool with a single support rack if possible.

In one embodiment, the projecting structure further includes aninterface post extending upwardly from the support panel. The interfacepost may be higher in height than the mounting panel, in someembodiments. The interface post includes a shaped periphery sized tofrictionally engage and fit within a receptacle aperture on the powerhand tool. To this end, the interface post closely simulates the shapeand size of a battery interface on a battery pack designed to engagewith the receptacle aperture of the power hand tool. The shapedperiphery of the interface post generally remains consistent along aheight of the interface post except at an upper free end of theinterface post. In this regard, the interface post further includesslots cutaway from the shaped periphery adjacent the upper free end tosimulate charging interface terminals on the battery pack designed toengage with the power hand tool.

In related embodiments, the projecting structure can further include apair of elongated rail-shaped projections having a height less than theheight of the interface post. One of the rail-shaped projections extendsgenerally parallel to the mounting panel at a location between themounting panel and the interface post, while another of the rail-shapedprojections extends generally parallel to the mounting panel at alocation on an opposite side of the interface post from the first of therail-shaped projections. The pair of elongated rail-shaped projectionsare configured to engage with additional portions of the power hand toolto further align and stabilize the power hand tool in position on thesupport panel when the power hand tool is engaged with the support rack.For example, the pair of elongated rail-shaped projections arepositioned on the support panel adjacent where snap-release couplingmembers are located on the power hand tool, the snap-release couplingmembers designed for removable engagement with similar coupling memberson the battery pack designed to engage with the power hand tool.

In a different embodiment, the projecting structure includes a T-shapedrail projection with a stem portion, which connects to and extendsupwardly from the upper surface of the support panel, and a top portionthat is generally planar and projects laterally beyond at least two sideedges of the stem portion such that the top portion has a greater widththan that of the stem portion. The T-shaped rail projection is shapedand sized to frictionally engage and fit within a receptacle slot on thepower hand tool. The T-shaped rail projection closely simulates theshape and size of a battery interface on a battery pack designed toengage with the receptacle slot of the power hand tool. The T-shapedrail projection may further include an end wall connected to each of thestem portion and the top portion. This end wall has a width consistentwith the width of the top portion such that opposing slots definedunderneath the top portion where it projects laterally beyond the stemportion are terminated by the end wall.

In a second set of embodiments, a method is provided for manufacturing asupport rack for hanging a power hand tool on a wall surface. The methodincludes conducting additive manufacturing or injection molding toproduce the support rack as an integral and unitary one-piececonstruction. The step of conducting is further defined by: forming amounting panel, forming a support panel, and forming at least oneprojecting structure. The mounting panel is configured to be positionedin engagement with the wall surface, and the mounting panel includes atleast one fastener aperture sized to receive a fastening element thatremovably couples the mounting panel to the wall surface. The supportpanel connects to and extends transversely away from the mounting panel,with the support panel having an upper surface and a lower surface. Theprojecting structure extends transversely and upwardly from the uppersurface of the support panel. The projecting structure is customized inshape and size to releasably engage in a frictional fit with at leastone corresponding interface aperture provided on the power hand tool.The support rack includes no metallic or conductive componentsconfigured to provide power or electrical charging to the power handtool.

In one such embodiment, the projecting structure is made by forming aninterface post and forming a pair of elongated rail-shaped projections.The interface post extends upwardly from the support panel and includesa shaped periphery sized to frictionally engage and fit within areceptacle aperture on the power hand tool. The rail-shaped projectionshave a lesser height than that of the interface post, with both of therail-shaped projections extending generally parallel to the mountingpanel, with one on each opposite side of the interface post. Therail-shaped projections are configured to engage with additionalportions of the power hand tool, such as for aligning and stabilizingthe tool on the support rack.

In another such embodiment, the projecting structure is made by forminga T-shaped rail projection with a stem portion and a top portion. Thestem portion connects to and extends upwardly from the upper surface ofthe support panel. The top portion is generally planar and projectslaterally beyond at least two side edges of the stem portion. TheT-shaped rail projection is shaped and sized to frictionally engage andfit within a receptacle slot on the power hand tool.

In a third set of embodiments, a method is provided for manufacturing asupport rack for hanging a battery pack on a wall surface. The methodincludes conducting additive manufacturing or injection molding toproduce the support rack as an integral and unitary one-piececonstruction. The step of conducting is further defined by: forming amounting panel, forming a support element, and forming at least onebattery aperture or battery slot. The mounting panel is configured to bepositioned in engagement with the wall surface, and the mounting panelincludes at least one fastener aperture sized to receive a fasteningelement that removably couples the mounting panel to the wall surface.The support element connects to and extends outwardly away from themounting panel, with the support element having an upper surface and alower surface. The battery aperture or slot extends into the supportelement from the upper surface thereof and towards the lower surfacethereof. Each battery aperture or battery slot is customized in shapeand size to releasably engage in a frictional fit with at least onecorresponding interface element provided on the battery pack. Thesupport rack includes no metallic or conductive components configured toprovide power or electrical charging to the battery pack.

In one such embodiment, the support element is a support panel that isgenerally planar in shape and extends outwardly at an oblique angle fromthe mounting panel. The support panel includes two or more batteryapertures in side-by-side relationship. Each of the battery aperturesextends through the support panel from the upper surface to the lowersurface such that a projecting portion of the battery pack is insertablethrough the battery apertures to provide physical support for thebattery pack at the support rack.

In another such embodiment, the support element includes a series ofsupport lugs each extending outwardly and perpendicularly from themounting panel. The support lugs are spaced apart laterally from oneanother along a length of the support rack so as to define frontopenings of two or more of the battery slots, such slots being definedbetween each adjacent pair of support lugs. Each of the battery slotsextends vertically in the support element from the upper surface thereofsuch that a rail-like interface element of the battery pack is slidableinto the battery slot to provide physical support for the battery packat the support rack.

It will be understood that the various embodiments described above canbe combined in any combination or sub-combination, without departingfrom the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute apart of this specification, illustrate one or more embodiments of theinvention and, together with a general description of the inventiongiven above, and the detailed description given below, serve to explainthe invention.

FIG. 1 is a top left perspective view of a tool support rack inaccordance with one embodiment of the present invention, the supportrack including an interface post.

FIG. 2 is a top right perspective view of the tool support rack of FIG.1 .

FIG. 3 is a perspective view schematically showing various uses of thetool support rack of FIG. 1 when mounted on a wall surface, withmultiple power hand tools shown for illustrative purposes in thisregard.

FIG. 4 is a top left perspective view of a tool support rack inaccordance with another embodiment of the present invention, the supportrack including a T-shaped rail projection.

FIG. 5 is a top right perspective view of the tool support rack of FIG.4 .

FIG. 6 is a top perspective view of a battery support rack in accordancewith yet another embodiment of the present invention, the support rackincluding a series of battery apertures with one exemplary battery packinserted into engagement with one of the battery apertures.

FIG. 7 is a top perspective view of a battery support rack in accordancewith a further embodiment of the present invention, the support rackincluding a series of battery slots with one exemplary battery pack slidinto engagement with one of the battery slots.

FIG. 8 is a top left isometric view of a battery holding storage racksubstantially similar to that shown in FIG. 6 , so as to show additionalfeatures, but with the apertures shown in phantom lines.

FIG. 9 is a top plan view of the storage rack of FIG. 8 .

FIG. 10 is a bottom plan view of the storage rack of FIG. 8 .

FIG. 11 is a front elevation view of the storage rack of FIG. 8 .

FIG. 12 is a rear elevation view of the storage rack of FIG. 8 .

FIG. 13 is a left side elevation view of the storage rack of FIG. 8 .

FIG. 14 is a right side elevation view of the storage rack of FIG. 8 .

FIG. 15 is a top left isometric view of the storage rack of FIG. 8 ,shown with one exemplary battery pack in phantom as well.

FIG. 16 is a top left isometric view of another embodiment of thebattery holding storage rack similar to those in FIGS. 6 and 8 , butincluding variation in rack width.

FIG. 17 is a top plan view of the storage rack of FIG. 16 .

FIG. 18 is a bottom plan view of the storage rack of FIG. 16 .

FIG. 19 is a front elevation view of the storage rack of FIG. 16 .

FIG. 20 is a rear elevation view of the storage rack of FIG. 16 .

FIG. 21 is a left side elevation view of the storage rack of FIG. 16 .

FIG. 22 is a right side elevation view of the storage rack of FIG. 16 .

FIG. 23 is a top left isometric view of a battery holding storage rackaccording to another embodiment.

FIG. 24 is a front elevation view of the storage rack of FIG. 23 .

FIG. 25 is a rear elevation view of the storage rack of FIG. 23 .

FIG. 26 is a top plan view of the storage rack of FIG. 23 .

FIG. 27 is a bottom plan view of the storage rack of FIG. 23 .

FIG. 28 is a left side elevation view of the storage rack of FIG. 23 .

FIG. 29 is a right side elevation view of the storage rack of FIG. 23 .

FIG. 30 is a top left isometric view of the battery holding storage rackof FIG. 23 , showing environmental structure in the form of a power toolbattery stored in position on the battery holding storage rack.

FIG. 31 is a top left isometric view of a battery holding storage rackaccording to another embodiment similar to the one shown in FIG. 23 (butincluding some features shown in phantom).

FIG. 32 is a front elevation view of the storage rack of FIG. 31 .

FIG. 33 is a rear elevation view of the storage rack of FIG. 31 .

FIG. 34 is a top plan view of the storage rack of FIG. 31 .

FIG. 35 is a bottom plan view of the storage rack of FIG. 31 .

FIG. 36 is a left side elevation view of the storage rack of FIG. 31 .

FIG. 37 is a right side elevation view of the storage rack of FIG. 31 .

FIG. 38 is a top left isometric view of a battery holding storage rackaccording to a further embodiment similar to the one shown in FIG. 23(but including some features and widths shown in phantom).

FIG. 39 is a front elevation view of the storage rack of FIG. 38 .

FIG. 40 is a rear elevation view of the storage rack of FIG. 38 .

FIG. 41 is a top plan view of the storage rack of FIG. 38 .

FIG. 42 is a bottom plan view of the storage rack of FIG. 38 .

FIG. 43 is a left side elevation view of the storage rack of FIG. 38 .

FIG. 44 is a right side elevation view of the storage rack of FIG. 38 .

FIG. 45 is a top left isometric view of a battery holding storage rackaccording to a further embodiment similar to the one shown in FIG. 23(but including further variations).

FIG. 46 is a front elevation view of the storage rack of FIG. 45 .

FIG. 47 is a rear elevation view of the storage rack of FIG. 45 .

FIG. 48 is a top plan view of the storage rack of FIG. 45 .

FIG. 49 is a bottom plan view of the storage rack of FIG. 45 .

FIG. 50 is a left side elevation view of the storage rack of FIG. 45 .

FIG. 51 is a right side elevation view of the storage rack of FIG. 45 .

FIG. 52 is a top left isometric view of a battery holding storage rackaccording to a different embodiment.

FIG. 53 is a front elevation view of the storage rack of FIG. 52 .

FIG. 54 is a rear elevation view of the storage rack of FIG. 52 .

FIG. 55 is a top plan view of the storage rack of FIG. 52 .

FIG. 56 is a bottom plan view of the storage rack of FIG. 52 .

FIG. 57 is a left side elevation view of the storage rack of FIG. 52 .

FIG. 58 is a right side elevation view of the storage rack of FIG. 52 .

FIG. 59 is a top left isometric view of the battery holding storage rackof FIG. 52 , showing environmental structure in the form of a power toolbattery stored in position on the battery holding storage rack.

FIG. 60 is a top left isometric view of a battery holding storage rackaccording to another embodiment similar to the one shown in FIG. 52 (butincluding some features shown in phantom).

FIG. 61 is a front elevation view of the storage rack of FIG. 60 .

FIG. 62 is a rear elevation view of the storage rack of FIG. 60 .

FIG. 63 is a top plan view of the storage rack of FIG. 60 .

FIG. 64 is a bottom plan view of the storage rack of FIG. 60 .

FIG. 65 is a left side elevation view of the storage rack of FIG. 60 .

FIG. 66 is a right side elevation view of the storage rack of FIG. 60 .

FIG. 67 is a top left isometric view of a battery holding storage rackaccording to a further embodiment similar to the one shown in FIG. 52(but including some features and widths shown in phantom).

FIG. 68 is a front elevation view of the storage rack of FIG. 67 .

FIG. 69 is a rear elevation view of the storage rack of FIG. 67 .

FIG. 70 is a top plan view of the storage rack of FIG. 67 .

FIG. 71 is a bottom plan view of the storage rack of FIG. 67 .

FIG. 72 is a left side elevation view of the storage rack of FIG. 67 .

FIG. 73 is a right side elevation view of the storage rack of FIG. 67 .

FIG. 74 is a top left isometric view of a battery holding storage rackaccording to a further embodiment similar to the one shown in FIG. 52(but including further variations).

FIG. 75 is a front elevation view of the storage rack of FIG. 74 .

FIG. 76 is a rear elevation view of the storage rack of FIG. 74 .

FIG. 77 is a top plan view of the storage rack of FIG. 74 .

FIG. 78 is a bottom plan view of the storage rack of FIG. 74 .

FIG. 79 is a left side elevation view of the storage rack of FIG. 74 .

FIG. 80 is a right side elevation view of the storage rack of FIG. 74 .

FIG. 81 is a top left isometric view of a battery holding storage rackaccording to another embodiment.

FIG. 82 is a front elevation view of the storage rack of FIG. 81 .

FIG. 83 is a rear elevation view of the storage rack of FIG. 81 .

FIG. 84 is a top plan view of the storage rack of FIG. 81 .

FIG. 85 is a bottom plan view of the storage rack of FIG. 81 .

FIG. 86 is a left side elevation view of the storage rack of FIG. 81 .

FIG. 87 is a right side elevation view of the storage rack of FIG. 81 .

FIG. 88 is a top left isometric view of a battery holding storage rackaccording to a further embodiment.

FIG. 89 is a front elevation view of the storage rack of FIG. 88 .

FIG. 90 is a rear elevation view of the storage rack of FIG. 88 .

FIG. 91 is a top plan view of the storage rack of FIG. 88 .

FIG. 92 is a bottom plan view of the storage rack of FIG. 88 .

FIG. 93 is a left side elevation view of the storage rack of FIG. 88 .

FIG. 94 is a right side elevation view of the storage rack of FIG. 88 .

FIG. 95 is a top left isometric view of a battery holding storage rackaccording to a different embodiment.

FIG. 96 is a front elevation view of the storage rack of FIG. 95 .

FIG. 97 is a rear elevation view of the storage rack of FIG. 95 .

FIG. 98 is a top plan view of the storage rack of FIG. 95 .

FIG. 99 is a bottom plan view of the storage rack of FIG. 95 .

FIG. 100 is a left side elevation view of the storage rack of FIG. 95 .

FIG. 101 is a right side elevation view of the storage rack of FIG. 95 .

FIG. 102 is a top left isometric view of a battery holding storage rackaccording to another embodiment.

FIG. 103 is a front elevation view of the storage rack of FIG. 102 .

FIG. 104 is a rear elevation view of the storage rack of FIG. 102 .

FIG. 105 is a top plan view of the storage rack of FIG. 102 .

FIG. 106 is a bottom plan view of the storage rack of FIG. 102 .

FIG. 107 is a left side elevation view of the storage rack of FIG. 102 .

FIG. 108 is a right side elevation view of the storage rack of FIG. 102.

FIG. 109 is a top left isometric view of a battery holding storage rackaccording to yet another embodiment.

FIG. 110 is a front elevation view of the storage rack of FIG. 109 .

FIG. 111 is a rear elevation view of the storage rack of FIG. 109 .

FIG. 112 is a top plan view of the storage rack of FIG. 109 .

FIG. 113 is a bottom plan view of the storage rack of FIG. 109 .

FIG. 114 is a left side elevation view of the storage rack of FIG. 109 .

FIG. 115 is a right side elevation view of the storage rack of FIG. 109.

DETAILED DESCRIPTION

Various embodiments of a support rack for retaining power hand toolsand/or associated battery packs are shown at FIGS. 1-7 and described indetail below. The support racks allow for a cost-efficient andsimplified method of manufacturing, while also providing secure andreliable support for organizing power hand tools and/or battery packsalong any surface, particularly wall surfaces. To this end, the supportracks are advantageously formed with no metallic or conductivecomponents configured to provide power or electrical charging, whichhelps simplify the construction and reduce the likelihood of failures inuse. Each support rack may be custom-tailored for particularmanufacturers or brands so that the correct battery pack or power handtool can be located and accessed on demand by tool users. As a result,the support racks and methods described herein improve organization andstorage for all tool users, whether in commercial settings or forpersonal household use.

With reference to FIGS. 1-3 , a first embodiment of a tool support rack10 is shown in detail. The tool support rack 10 is configured to providea reliable physical support for a power hand tool as will be explainedin further detail below. The tool support rack 10 includes a mountingpanel 12, a support panel 14 connected to and extending transverselyoutward from the mounting panel 12, and at least one projectingstructure extending upwardly from the support panel 14. In thisembodiment, the projecting structure is defined by an interface post 16and a pair of elongated rail-shaped projections 18 on opposite sides ofthe interface post 16. The tool support rack 10 is therefore configuredto releasably engage in a frictional fit with at least one correspondinginterface aperture or slot provided on one or more power hand tools.Each power hand tool may have a similar interface for engaging with thebattery packs used with that type of power hand tool, but it will beappreciated that the tool support rack 10 engages with and supports onlyone power hand tool at a time in this embodiment.

The mounting panel 12 and the support panel 14 collectively define anL-shaped configuration when viewed from the side in this embodiment, asis evident in FIGS. 1 and 2 . This L-shaped configuration is a result ofboth the mounting panel 12 and the support panel 14 being formed as aplanar panel, with the panels 12, 14 being generally perpendicular toone another. To help avoid a stress concentration point whenmanufacturing the tool support rack 10, such as by additivemanufacturing methods like 3D printing or injection molding, theinterior junction 20 between the panels 12, 14 is formed as a curvedtransition portion.

With reference to the mounting panel 12, the planar panel defines aU-shaped construction including a main wall portion 24 that extendsalong an entirety of the width of the mounting panel 12 and two mountingtabs 26 that project vertically above the main wall portion 24 onopposite ends of the width the mounting panel 12. Each of the mountingtabs 26 is generally rectangular in shape but includes corner chamfers28 both at the upper corners thereof as well as at the lower cornerdefining a transition junction with the top end of the main wall portion24. As such, the mounting tabs 26 provide a smoothened upper peripheryand ornamental appearance for the mounting panel 12, which furtherenhances the U-shaped construction thereof. Each of the mounting tabs 26extends with a height in this embodiment about the same height, orslightly less than, the height of the main wall portion 24, although itwill be understood that the relative shape and sizes of these elementsof the mounting panel 12 may be modified in other embodiments. Likewise,the mounting panel 12 may be formed with more than two mounting tabs 26in further embodiments of the support rack 10, such as ones that arelarger in size than this illustrated embodiment for supporting largerpower hand tools. Each of the mounting tabs 26 includes a fasteneraperture 30 formed as a cylindrical bore through the thickness of themounting panel 12, e.g., from a front surface 32 of the mounting panel12 through to the back surface 34 thereof. Each fastener aperture 30 issized to receive a fastening element 36 (see FIG. 3 ) such as a screw orwall anchor that removably couples the mounting panel 12 to a wallsurface.

To this end, when the tool support rack 10 of this embodiment isinstalled on a wall surface (not shown), the back surface 34 of themounting panel 12 is positioned in abutting parallel contact with thewall surface in the desired location, and then the fastening elements 36secure the tool support rack 10 in position on the wall surface. Thisconfiguration permits the tool support rack 10 to be securely attachedto the wall surface but also removable, in the event a reconfigurationor reorganization of the tool and battery storage space is desired bythe end user. Such reconfiguration may become desirable if the set ofpower hand tools that are to be stored on the tool support rack 10 varyin size and shape and therefore require more room around the toolsupport rack 10 when in use on the wall surface. In the securedconfiguration along the wall surface, the front surface 32 and thecurved interior junction 20 between the panels 12, 14 faces outwardlytowards the support panel 14 and towards the projecting structure(s) onthat support panel 14.

Now turning to the support panel 14, the planar panel construction ofthe support panel 14 defines an upper surface 40, a lower surface 42,and a peripheral edge 44 extending between the upper surface 40 andlower surface 42. The support panel 14 defines a generally square orrectilinear shape, which results in the peripheral edge including acouple of front corner portions 46 which in this embodiment are roundedso as to avoid stress concentrations during manufacturing and also avoidsharp corner edges at a leading end of the tool support rack 10. Thesupport panel 14 thus defines a width concurrent with the width of themounting panel 12 in this embodiment, which positions the fasteningelements 36 in the mounting tabs 26 for evenly supporting an entirety ofthe tool support rack 10 and any power hand tool mounted thereon asdescribed in examples below. When the mounting panel 12 is secured alonga generally vertical wall surface, the support panel 14 is orientedgenerally horizontally, and it is with this frame of reference that theupper surface 40 and the lower surface 42 are labeled in thisdescription.

The interface post 16 and the rail-shaped projections 18 extendgenerally transversely upward from the upper surface 40 of support panel14. In this embodiment, the interface post 16 defines a shaped periphery50 that is sized to frictionally engage and fit within a receptacleaperture on a power hand tool. The shaped periphery 50 in FIGS. 1 and 2generally includes three planar sidewalls and a fourth convex roundedsidewall, each of which extend up to a top end 52 of the interface post16. More specifically, the illustrated version of the interface post 16has a shaped periphery 50 designed with a similar shape and size as thecharging terminal projection 54 location on rechargeable 18V batterypacks 56 (see FIG. 3 ), such as those commercially available from RyobiSeisakusho Co., Ltd., of Japan. It will be appreciated that theparticular shape and size of the interface post 16 may be reconfiguredin other embodiments of the invention so that different types of powerhand tools may be supported on the tool support rack 10.

With continued reference to FIGS. 1 and 2 , the shaped periphery 50 ofthe interface post 16 remains generally consistent along a height of theinterface post 16, with one exception. Adjacent the top end 52, e.g.,along an upper free end of interface post 16, the three planar sidewallsof the shaped periphery 50 further include cutaway slots 58 thatsimulate the shape and position of charging terminals 60 that arepresent on the charging terminal projection 54 of the battery pack 56.The specific size and arrangement of such cutaway slots 58 may bemodified in other embodiments so as to closely simulate or matchdifferent interfaces of other battery packs and other toolmanufacturers. In all embodiments, the interface post 16 is specificallyformed to engage in a close frictional fit with the power hand tool inorder to reliably secure the power hand tool in position on the supportpanel 14.

The elongated rail-shaped projections 18 are also shown in furtherdetail in FIGS. 1 and 2 for this embodiment. Each of the rail-shapedprojections 18 defines a shorter height than the height of the interfacepost 16, and more specifically, a shorter height than the height of themounting panel 12 as well. The rail-shaped projections 18 extendgenerally linearly between opposing rounded ends 62. Both of therail-shaped projections 18 extend along this linear path generallyparallel to the mounting panel 12, which results in the rounded ends 62facing towards the lateral sides on opposite ends of the width of thesupport panel 14. One of the rounded ends 62 for the rail-shapedprojections 18 is located in a concurrent position as the interface post16 along a lateral width of the support panel 14, and more specifically,this rounded end 62 terminates at about a center of the width of theinterface post 16. The opposite of the rounded ends 62 on bothrail-shaped projections 18 is thus closer to one lateral side of thesupport panel 14 and located away from the interface post 16 such thatthe rail-shaped projections 18 effectively bracket and then extend awayfrom the interface post 16, the latter being located generally centrally(or slightly offset from center) on the support panel 14. One of therail-shaped projections 18 is located between the interface post 16 andthe mounting panel 12, so as to be generally behind the interface post16 when looking at the tool support rack 10 from a front end thereof,and another of the rail-shaped projections 18 is located on an oppositeside of the interface post 16 closer to the front end of the supportpanel 14.

In the illustrated embodiment, which as noted above is designed fortools made by the Ryobi company in this example, the pair of elongatedrail-shaped projections 18 are configured with a shape and size forengaging additional portions of the power hand tool. For example, therail-shaped projections 18 are positioned on the support panel 14adjacent where snap-release coupling members 64 are located on the powerhand tool [not visible in the Figures] and on the correspondingremovable battery pack 56 (again, see FIG. 3 ). The snap-releasecoupling members 64 and the rail-shaped projections 18 thereforeremovably engage with the same interface structures on the power handtool. This engagement with the rail-shaped projections 18 when on thetool support rack 10 is designed to further align and stabilize thepower hand tool in position on the tool support rack 10. The rail-shapedprojections 18 may be reshaped, repositioned, or omitted altogether inother embodiments of the support rack, but when present, theserail-shaped projections 18 assist with making a more reliable andconsistent physical support of the power hand tool on the tool supportrack 10.

The tool support rack 10 as shown in FIGS. 1-3 may be made by a methodof manufacture in accordance with further embodiments of the invention.The method of manufacture includes conducting at least one of additivemanufacturing (e.g., 3D printing) or injection molding to produce thetool support rack 10 with all of the elements described above, includingthe mounting panel 12, the support panel 14, and the at least oneprojecting structure on top of the support panel 14. In both these typesof forming, the tool support rack 10 is advantageously formed from andconsists of a plastic material, which is lightweight but strong enoughto support various power hand tools. To this end, the desirable strengthof the tool support rack 10 is in part a result of forming all of theelements of the tool support rack 10 integrally as a unitary piece fromthe plastic material, and in part from forming the mounting panel 12 andthe support panel 14 with a sufficient size and thickness that willsupport a full weight of the power hand tool when such tool is engagedwith the at least one projecting structure. With each line ormanufacturer typically using a consistent battery pack design forsupporting a plurality of different power hand tools, the mold forinjection molding and the plans for 3D printing only requiremodification to adjust the shape and size of the at least one projectingstructure to accommodate and produce tool support racks 10 of differentembodiments for different types and makers of tools and battery packs.For strength and manufacturing speed and reliability, injection moldingis preferred, but these and other similar types of manufacturing arepossible for performing this step of the method of manufacture.

As described above, the forming of the tool support rack 10 to consistof just the plastic material also advantageously results in the toolsupport rack 10 having no metallic or conductive components, which wouldsignificantly increase cost and complexity to manufacture, while alsorequiring separate connection of the rack to an external power supply,which may not always be possible or desirable when organizing andstoring/supporting tools. The tool support rack 10 of this inventionallows for custom-tailored supports and organization to be applied inmany different household and commercial settings, which thereby improvesthe practices of users of these sets of power hand tools. Moreover, theclose frictional fit provided for power hand tools allows betterphysical support and higher reliability and predictability for users,effectively presenting a superior option for storage of power hand toolsas compared to any conventional designs.

Now with reference to FIG. 3 , one potential use of the tool supportrack 10 of the previously-described and illustrated embodiment is shownin further detail. To this end, the user may own various power handtools that are configured to be powered by the same battery pack 56, thespecific examples shown including a mobile flashlight 66 and a cordlessdrill 68. Each of the power hand tools 66, 68 includes a batteryinterface 70 which is shown along a bottom of these power hand tools 66,68, the battery interface 70 including a receptacle aperture and/orsnap-release coupling members as noted above. As a result, when a useris done with the flashlight 66 and needs to begin work with the cordlessdrill 68, the cordless drill 68 can be disengaged from the storageposition on the tool support rack 10 (shown by phantom lines in FIG. 3and movement arrow 72), and then moved as shown by arrow 74 to engagewith the battery pack 56, which may have been previously removed fromthe flashlight 66. With the tool support rack 10 now opened up again andavailable, the flashlight 66 can be engaged with the interface post 16and rail-shaped projections 18 to secure the flashlight 66 in positionat the tool support rack 10. The flashlight 66 is protected fromaccidental damages and positioned to be ready for the next time the userneeds this tool. Accordingly, the tool support rack 10 may be used toprovide physical support to any one of a number of different power handtools, as the need arises and as the user desires at that time.

FIGS. 4 and 5 illustrate an alternative embodiment of the tool supportrack 110, this tool support rack 110 being similar in many elements andmanners as the previously described embodiment. To this end, the samereference numbers including 12, 14 are used on elements such as themounting panel 12 and the support panel 14 where those elements areunchanged from the prior embodiment, for the sake of descriptionefficiency. The tool support rack 110 of this embodiment includes adifferent type of projecting structure extending upwardly from thesupport panel 14. In this particular example, the projecting structureis designed to interface with power hand tools in the same manner as theconnection/charging interface on rechargeable 20V battery packs, such asthose commercially available from Dewalt Industrial Tool Co., ofMaryland.

More particularly, the projecting structure of this embodiment includesa T-shaped rail projection 180 extending upwardly from about a center ofthe support panel 14. The T-shaped rail projection 180 is defined by astem portion 182 and a top portion 184. The stem portion 182 connects toand extends from the upper surface 40 of support panel 14. The topportion 184 is generally planar and extends so as to project laterallybeyond the corresponding sides of the stem portion 182 adjacent at leasttwo side edges 186 defined by the top portion 184. As shown in FIGS. 4and 5 , these side edges 186 may be the front-facing and rear-facingside edges 186 of the top portion 184, such that the general T-shapedconstruction of the rail projection 180 is most clearly visible from theside of the tool support rack 110. The top portion 184 along the sideedges 186 and the stem portion 182 collectively define opposing slots188 that extend along a width of the T-shaped rail projection 180,specifically along the opposite sides of the T-shape. The corners of thetop portion 184 may taper slightly over the open end of the opposingslots 188 as shown. The opposing slots 188 are sized and shaped to beconfigured for engagement with a receptacle slot defining a batteryinterface on a power hand tool (which in this illustrated example wouldbe a tool that works with 20V Dewalt battery packs).

The T-shaped rail projection 180 of this embodiment includes additionalfeatures. To this end, the rail projection 180 further includes an endwall 190 connected to each of the stem portion 182 and to the topportion 184. The end wall 190 has a length consistent with the topportion 184 and therefore also projects over one end of the opposingslots 188, shown along the left side of the rail projection 180 in FIGS.4 and 5 . As such, the T-shaped rail projection 180 of this embodiment“opens” towards a right side of the tool support rack 110, but it willbe understood that the end wall 190 could be repositioned to differentsides such that a power hand tool is slid onto the T-shaped railprojection 180 in different directions in similar alternativeembodiments. In its entirety, the T-shaped rail projection 180 closelysimulates the shape and size of a battery interface on a battery packdesigned to engage with the receptacle slot on one or more power handtools, which results in the power hand tools being engagable in a closefrictional fit with the T-shaped rail projection 180 to physicallysupport the power hand tool on the tool support rack 110 of thisembodiment. In corresponding methods of manufacture, the rail projection180 is formed integrally as a unitary piece of the same plastic materialas the mounting panel 12 and as the support panel 14, therebyfunctioning in an identical manner as the previously-describedembodiment. Also as described above, these illustrated embodiments arejust two specific examples showing the variations possible for the atleast one projecting structure provided atop the support panel 14 of thetool support racks 10, 110, and further embodiments custom-tailored forother brands or lines of power hand tools can achieve the same technicalbenefits in other embodiments of the present invention.

Support racks in accordance with the embodiments of this invention mayalso be reconfigured to physically support a plurality of rechargeablebattery packs along the wall surface. Two specific examples ofalternative embodiments of the support rack are shown in FIGS. 6 and 7 .In many respects, these support racks have similar elements andconstruction methods as the above-described tool support racks 10, 110.However, a brief description of these alternatives follows to explainthe differences, where present.

The support rack 210 shown in FIG. 6 is designed for battery packs 256having interface post charging projections 276 such as those used with18V tools commercially available from the Ryobi company, but as withprior embodiments, the support rack 210 is custom-tailored to anyspecific type or line of battery pack 256 desired for organization andstorage. The support rack 210 is an angled battery rack which includes amounting panel 212 that is configured to be positioned in engagementwith the wall surface, a support panel 214 that is generally planar inshape and extends outwardly at an oblique angle from the mounting panel212, and a plurality of battery apertures 216 that are formed inside-by-side relationship along a width of the support panel 214. Eachof the battery apertures 216 extends through the support panel 214completely, e.g., from the upper surface 240 thereof through the lowersurface 242 thereof. Moreover, each battery aperture 216 is sized andshaped to releasably engage in a close frictional fit with thecorresponding interface element on the battery pack 256, which as notedabove is an interface post charging projection 276 in this illustratedembodiment.

Although only one battery pack 256 is shown at the support rack 210 inFIG. 6 , it will be readily understood that a series of battery packs256 can be stored in side-by-side relationship by inserting theinterface post charging projections 276 into frictional fits with thebattery apertures 216 on the support panel 214. As with previousembodiments, the mounting panel 212 includes fastener apertures 230(specifically, at tabs 226 that project beyond each side edge of thesupport panel 214) such that the support rack 210 can be mounted along awall surface, and when this mounting is done, the oblique angling of thesupport rack 210 presents each of the battery packs 256 in a positionthat is easy to access for users when a battery pack 256 in the supportrack 210 is needed for use with a power hand tool. The elements of thesupport rack 210 are again formed with rounded corners, junctions, andchamfers to provide a smooth ornamental appearance without any sharpcorners that would be stress concentration points or potential pointsfor users to catch themselves or tools upon. Just like thepreviously-described embodiments, the support rack 210 is advantageouslyformed by additive manufacturing or injection molding from a plasticmaterial (and integrally formed as a unitary piece for the necessarystrength and reliability desired), so as to not include any metallic orconductive components for providing power or charging to the batterypacks. Thus, the support rack 210 is configured to provide physicalsupport and organization only for the battery pack(s) 256. In similaralternative embodiments, the size and shape of the battery apertures 216is modified to receive the interface elements of different styles ofbattery packs.

Now turning to FIG. 7 , the support rack 310 shown in this embodiment isdesigned for battery packs 356 having charging interfaces in the form ofrail-shaped projections 378 such as those used with 12V toolscommercially available from Milwaukee Electric Tool Corp., of Wisconsin,but as with prior embodiments, the support rack 310 is custom-tailoredto any specific type or line of battery pack 356 having various railprojections that would be desired for organization and storage. Thesupport rack 310 is a vertical slot battery rack which includes amounting panel 312 that is configured to be positioned in engagementwith the wall surface, a support element 314 defined by a series ofsupport lugs 380 that each extend outwardly and perpendicular from themounting panel 312, and a plurality of battery slots 316 that are formedin side-by-side relationship between adjacent pairs of the support lugs380. Each of the battery slots 316 in the support rack 310 of thisembodiment extends from a top surface 340 of the support rack 310 andthrough a bottom surface 342 of the support rack 310, whichadvantageously allows for battery packs 356 to be stored in a mannerrelatively centered on the height of the support rack 310 (e.g., thebattery pack 356 when stored projects a similar amount above the topsurface 340 and below the bottom surface 342 thereof). Moreover, eachbattery slot 316 is sized and shaped to releasably engage in a closefrictional fit with the corresponding interface element on the batterypack 356, which as noted above is a rail projection 378 in thisillustrated embodiment.

Though only one battery pack 356 is shown at the support rack 310 inFIG. 7 , it will be readily understood that a series of battery packs356 can be stored in side-by-side relationship by inserting the railprojections 378 into frictional fits with the battery slots 316. As withprevious embodiments, the mounting panel 312 includes fastener apertures330 (specifically in this embodiment, also extending through to a frontof selected ones of the support lugs 380 as well) such that the supportrack 310 can be mounted along a wall surface. It will be appreciatedthat the fastener apertures 330 can be repositioned such as to be behindone or more of the battery slots 316 rather than through the supportlugs 380 in other embodiments of this invention. The elements of thesupport rack 310 are again formed with rounded corners, junctions, andchamfers to provide a smooth ornamental appearance without any sharpcorners that would be stress concentration points or potential pointsfor users to catch themselves or tools upon. Just like thepreviously-described embodiments, the support rack 310 is advantageouslyformed by additive manufacturing or injection molding from a plasticmaterial (and integrally formed as a unitary piece for the necessarystrength and reliability desired), so as to not include any metallic orconductive components for providing power or charging to the batterypacks. Thus, the support rack 310 is configured to provide physicalsupport and organization only for the battery pack(s) 356 of thisgeneral type. And like before, only the specific size and shape profilesof the vertical battery slots 356 (and the support lugs 380 definingsame) need to be modified in similar alternative embodiments that workwith other brands or lines of battery packs.

Further (similar) embodiments of the battery support racks are shown inFIGS. 8 through 115 . With respect to FIG. 8 as an example, it can beclearly seen that the mounting panel runs along an entire width of thesupport rack between the tabs—furthermore, this is a panel as indicatedthroughout this description, and the oblique angling of the mountingpanel from the support panel is shown in the side views along FIGS. 13and 14 . This oblique angling is defined by the acute angle measurablebetween the planar extent of the support panel/element and the generallyvertical extent of the mounting panel/element. These Figures (in eachsubsequent embodiment) also show that the battery receptacles orapertures are formed with a non-circular peripheral shape when viewedfrom above, with each of the battery receptacles also being formed to beidentical in shape and size to ach other battery receptacle or apertureon the support element. As such, a corresponding battery pack can beengaged in any position along the width of the support rack. Theseembodiments with the oblique angling shown in FIGS. 6 and 8-22 hold thebattery packs at an angle from a vertical orientation, so as to presenteach battery pack for ready access by a user.

As also shown in FIGS. 8 through 22 , the support rack of theseembodiments includes no structure extending below the batteryreceptacles from the lower surface of the support element. As such, aportion of each battery pack inserted through the battery receptaclesextends into open space located below the support rack. To this end,there are no closed receptacles or the like receiving these free ends ofthe battery packs, nor is the support rack configured to support itselfalong a tabletop or horizontal surface—this support rack is exclusivelydesigned for wall mounting. Each of these further embodiments is alsoformed by injection molding or the like to generate a unitary, one-piececonstruction (which is defined as formation by one material and nothaving individual components/parts that are formed from differentmaterials—this also improves and enhances the strength provided withinthe support rack to withstand the loads presented by the batterypack(s). It will be appreciated that the mounting panel may haveportions that extend (like the tabs) in any direction for convenientsecuring with fasteners to the wall, including above or below the backend of the support panel, without departing from the scope of thisinvention, but the embodiments specifically shown have been proven towork in practice by the original Applicant of this application.

Further embodiments of the battery support racks configured to receiverail-shaped projections like the one shown in FIG. 7 are also shown inFIGS. 23 through 115 . In each of these embodiments, the battery packsare configured to slot into receptacles and be held in generallyvertical orientation along the wall surface. In embodiments (most of theones shown) where the battery slots extend through an entire height ofthe support rack, there are no closed receptacles or the like receivingfree ends of the battery packs inserted through the battery slot(s), noris the support rack generally configured to support itself along atabletop or horizontal surface (even though it hypothetically could,that would undermine the ability for battery packs to project above andbelow the support racks as is typical during storage)—this support rackis exclusively designed for wall mounting. Even though the particularshape of the battery slots varies in the embodiments shown in FIGS.23-115 , in each case the “irregular” shape profile (as viewed from topor bottom view) is identical and repeated for each battery slot on thebattery rack, thereby enabling multiples of the same battery pack to bestored on the rack. The battery slots, much like the battery aperturesdescribed above, are shaped and sized to releasably engage in africtional fit with at least one corresponding interface element(typically a rail) provided on a battery pack.

Even though the fastener apertures are shown in FIGS. 23 through 115 tooften be located between battery slots, a mounting panel may extendabove or below the location of the battery slots in other embodimentsfor receiving the fasteners for mounting the support rack on the wall.Likewise, one or more of the support lugs may be formed with hollowportions or as walls to the battery slots (see, e.g., FIGS. 52-80 ) tosave on material use at these elements. Nevertheless, each of thesefurther embodiments is also formed by injection molding or the like togenerate a unitary, one-piece construction (which is defined asformation by one material and not having individual components/partsthat are formed from different materials—this also improves and enhancesthe strength provided within the support rack to withstand the loadspresented by the battery pack(s).

In all embodiments of the support rack of the present inventionincluding those described in detail in this section, a physical supportis provided for a power hand tool or one or more battery packs so thatthese can be organized and supported along a vertical wall surface. Thesimplified manufacturing methods provide for cost-efficiency while alsoachieving strength and reliability for the support racks, andcustom-tailoring the support racks for different styles of battery/toolinterfaces can also be done. Thus, owners and operators of power handtools and their battery packs can better organize and access these itemswhen needed, while reducing the likelihood of accidental damages andmisplacement of tools and battery packs. The support racks of thisinvention allow for secure physical storage of both power hand tools andbattery packs, thereby improving the options available in the field.

While the invention has been illustrated by a description of variousembodiments, and while these embodiments have been described inconsiderable detail, it is not the intention of the Applicant torestrict or in any way limit the scope of the appended claims to suchdetail. Additional advantages and modifications will readily appear tothose skilled in the art. The invention in its broader aspects istherefore not limited to the specific details, representative apparatusand methods, and illustrative examples shown and described. Accordingly,departures may be made from such details without departing from thescope of the Applicant's general inventive concept.

What is claimed is:
 1. A tool support rack for retaining a power handtool on a wall surface, comprising: a mounting panel configured to bepositioned in engagement with the wall surface, the mounting panelincluding at least one fastener aperture sized to receive a fasteningelement that removably couples the mounting panel to the wall surface; asupport panel connected to and extending transverse from the mountingpanel, the support panel including an upper surface and a lower surface;and at least one projecting structure extending transversely andupwardly from the upper surface of the support panel, wherein the atleast one projecting structure is customized in shape and size toreleasably engage in a frictional fit with at least one correspondinginterface aperture or slot provided on the power hand tool, the toolsupport rack including no metallic or conductive components configuredto provide power or electric charging to the power hand tool, such thatthe tool support rack provides only a physical support for the powerhand tool on the wall surface.
 2. The tool support rack of claim 1,wherein each of the mounting panel and the support panel is a planarpanel, and the support panel extends perpendicular to the mountingpanel, such that the support panel is oriented horizontally when thesupport panel is secured to the wall surface.
 3. The tool support rackof claim 2, wherein the mounting panel defines a U-shaped constructionwith mounting tabs extending vertically above a remainder of themounting panel on opposite lateral ends of the mounting panel.
 4. Thetool support rack of claim 3, wherein each of the mounting tabs includesone of the fastener apertures such that a plurality of fasteners may beused to secure the tool support rack to the wall surface.
 5. The toolsupport rack of claim 1, wherein the tool support rack is formed fromand consists of a plastic material only.
 6. The tool support rack ofclaim 5, wherein all of the mounting panel, the support panel, and theat least one projecting structure are formed integrally as a unitarypiece by additive manufacturing with the plastic material.
 7. The toolsupport rack of claim 5, wherein all of the mounting panel, the supportpanel, and the at least one projecting structure are formed integrallyas a unitary piece by injection molding the plastic material.
 8. Thetool support rack of claim 1, wherein the mounting panel and the supportpanel define a thickness and size configured to support a full weight ofthe power hand tool when the power hand tool is engaged in thefrictional fit with the at least one projecting structure.
 9. The toolsupport rack of claim 1, wherein the projecting structure furthercomprises: an interface post extending upwardly from the support panel,the interface post including a shaped periphery sized to frictionallyengage and fit within a receptacle aperture on the power hand tool, theinterface post thereby closely simulating the shape and size of abattery interface on a battery pack designed to engage with thereceptacle aperture of the power hand tool.
 10. The tool support rack ofclaim 9, wherein the shaped periphery of the interface post remainsconsistent along a height of the interface post except at an upper freeend of the interface post, and the interface post includes slots cutawayfrom the shaped periphery adjacent the upper free end to simulatecharging interface terminals on the battery pack designed to engage withthe power hand tool.
 11. The tool support rack of claim 9, wherein theprojecting structure further comprises: a pair of elongated rail-shapedprojections having a height less than a height of the interface post,with a first of the elongated rail-shaped projections extendinggenerally parallel to the mounting panel at a location between themounting panel and the interface post, and with a second of theelongated rail-shaped projections extending generally parallel to themounting panel at a location on an opposite side of the interface postfrom the first of the elongated rail-shaped projections, wherein thepair of elongated rail-shaped projections are configured to engage withadditional portions of the power hand tool to further align andstabilize the power hand tool in position on the support panel when thepower hand tool is engaged with the tool support rack.
 12. The toolsupport rack of claim 11, wherein the pair of elongated rail-shapedprojections are positioned on the support panel adjacent wheresnap-release coupling members are located on the power hand tool, thesnap-release coupling members designed for removable engagement withsimilar coupling members on the battery pack designed to engage with thepower hand tool.
 13. The tool support rack of claim 1, the at least oneprojecting structure further comprising: a T-shaped rail projectionincluding a stem portion, which is connected to and extending upwardlyfrom the upper surface of the support panel, and a top portion that isgenerally planar and projects laterally beyond at least two side edgesof the stem portion such that the top portion has a width greater than awidth of the stem portion, the T-shaped rail projection being shaped andsized to frictionally engage and fit within a receptacle slot on thepower hand tool, the T-shaped rail projection thereby closely simulatingthe shape and size of a battery interface on a battery pack designed toengage with the receptacle slot of the power hand tool.
 14. The toolsupport rack of claim 13, wherein the T-shaped rail projection furthercomprises an end wall connected to each of the stem portion and the topportion, the end wall having a width consistent with the width of thetop portion, and such that opposing slots defined underneath the topportion where it projects laterally beyond the stem portion areterminated by the end wall.
 15. A method of manufacturing a support rackfor hanging a power hand tool on a wall surface, the method comprising:conducting at least one of additive manufacturing and injection moldingto produce the support rack as an integral and unitary one-piececonstruction, wherein this step of conducting further comprises: forminga mounting panel that is configured to be positioned in engagement withthe wall surface, the mounting panel including at least one fasteneraperture sized to receive a fastening element that removably couples themounting panel to the wall surface; forming a support panel that isconnected to and extends transversely away from the mounting panel, thesupport panel including an upper surface and a lower surface; andforming at least one projecting structure extending transversely andupwardly from the upper surface of the support panel, wherein theprojecting structure is customized in shape and size to releasablyengage in a frictional fit with at least one corresponding interfaceaperture provided on the power hand tool, wherein the support rackincludes no metallic or conductive components configured to providepower or electrical charging to the power hand tool, such that thesupport rack provides only a physical support for the power hand tool onthe wall surface.
 16. The method of claim 15, wherein the step offorming the projecting structure further comprises: forming an interfacepost extending upwardly from the support panel, the interface postincluding a shaped periphery sized to frictionally engage and fit withina receptacle aperture on the power hand tool to support the power handtool on the support rack; and forming a pair of elongated rail-shapedprojections having a height less than a height of the interface post,with a first of the elongated rail-shaped projections extendinggenerally parallel to the mounting panel at a location between themounting panel and the interface post, and with a second of theelongated rail-shaped projections extending generally parallel to themounting panel at a location on an opposite side of the interface postfrom the first of the elongated rail-shaped projections, wherein thepair of elongated rail-shaped projections are configured to engage withadditional portions of the power hand tool to align and stabilize thepower hand tool in position.
 17. The method of claim 15, wherein thestep of forming the projecting structure further comprises: forming aT-shaped rail projection including a stem portion, which is connected toand extending upwardly from the upper surface of the support panel, anda top portion that is generally planar and projects laterally beyond atleast two side edges of the stem portion such that the top portion has awidth greater than a width of the stem portion, the T-shaped railprojection being shaped and sized to frictionally engage and fit withina receptacle slot on the power hand tool to support the power hand toolon the support rack.
 18. A support rack for retaining at least onebattery pack on a wall surface, the support rack comprising: a mountingpanel configured to be positioned in engagement with the wall surface,the mounting panel including at least one fastener aperture sized toreceive a fastening element that removably couples the mounting panel tothe wall surface; a support element connected to and extending outwardlyfrom the mounting panel, the support element including an upper surfaceand a lower surface; and a plurality of battery receptacles arranged inside-by-side relationship along a width of the support element, witheach of the battery receptacles extending from the upper surface thereofand to the lower surface thereof, wherein each of the batteryreceptacles is shaped and sized to releasably engage in a frictional fitwith at least one corresponding interface element provided on a batterypack, and wherein the mounting panel and support element are formed asan integral and unitary one-piece construction, wherein the supportelement is a support panel that is generally planar in shape and extendsat an oblique angle from the mounting panel, such that each battery packinserted into one of the plurality of battery receptacles is held at anangle from a vertical orientation, thereby presenting each battery packfor ready access by a user, and wherein the support rack includes nostructure extending below the battery receptacles from the lower surfaceof the support panel, such that a portion of each battery pack insertedthrough the battery receptacles extends into open space located belowthe support rack.
 19. The support rack of claim 18, wherein each of theplurality of battery receptacles is formed to define a non-circularperipheral shape when viewed from above the support panel.
 20. Thesupport rack of claim 19, wherein each of the battery receptacles isalso formed to be identical in shape and size to all other batteryreceptacles on the support panel.